CN114251727A - Multi-mode control method for air conditioner with front panel - Google Patents

Abstract

The invention relates to the field of air conditioners, in particular to a multi-mode control method for an air conditioner with a front panel. The multi-mode control method is provided with at least one functional mode, wherein the functional mode is one of a shutdown mode, a soft wind mode, a horizontal wind outlet mode, a side wind mode, a quick refrigeration mode, an angle wind supply mode, a heating vertical mode and a small wind mode; according to the invention, a plurality of functional modes are set, and the functional modes are realized by controlling the rotation position of the air deflector and/or the movement position of the front panel in a matching manner, so that the requirements of a plurality of functional modes based on the front panel air conditioner are met, different working environments or user requirements are met, the user experience is improved, and the multi-mode control mode of the front panel air conditioner is optimized.

Description

Multi-mode control method for air conditioner with front panel

Technical Field

The invention relates to the field of air conditioners, in particular to a multi-mode control method for an air conditioner with a front panel.

Background

Air conditioners (Air conditioners) are Air conditioners. The device is used for manually regulating and controlling parameters such as temperature, humidity, flow rate and the like of ambient air in a building or a structure.

Compared with a common air conditioner, the application of various modes is realized by mostly utilizing the blowing strength of a fan and the swing position of an air deflector, the application requirements of different environments or the special requirements of users cannot be met, especially the mastering of the wind speed and the wind volume is difficult to realize refinement, and the cost performance is low and the large-scale production and sale cannot be realized unless a high-cost high-precision functional structure is adopted.

Particularly, for an air conditioner with a front panel, although an existing front panel air conditioner can utilize the front panel to realize various operations which are difficult to realize by a common air conditioner, such as a soft wind mode, and realize soft wind without changing the interior of the air conditioner, the specific function mode is still single, which cannot meet the requirements of users, and the user experience is poor.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide a multi-mode control method for an air conditioner with a front panel, which solves the problem of poor user experience of the existing air conditioner.

The technical scheme adopted by the invention for solving the technical problems is as follows: the multi-mode control method is characterized in that the air conditioner comprises a middle frame, a lower air outlet arranged on the middle frame and an air deflector arranged at the lower air outlet of the middle frame, wherein the front panel is movably arranged on the front end surface of the middle frame, and forms an air outlet channel when moving back and forth relative to the front end surface; and the functional mode is realized by controlling the rotation position of the air deflector and/or the movement position of the front panel in a matching way.

Wherein, preferred scheme is, the air conditioner still includes the activity switch door, the shutdown mode includes:

the front panel is returned to the middle frame;

the air deflector is arranged on the lower end face of the lower air outlet;

the movable switch door extends out of the front end of the lower air outlet and is abutted against or close to the air deflector.

Preferably, the gentle wind mode includes:

the front panel can move back and forth or move up and down relative to the middle frame;

the air deflector is arranged on the lower end face of the lower air outlet;

wherein, the wind part that lower air outlet blew out is gone into in the air-out passageway, and control front panel motion and adjust its spatial position to the intake of control air-out passageway.

Wherein, preferred scheme is, the step of the air inlet volume of control air-out passageway is including controlling the front panel motion and adjusting its spatial position:

the front panel moves back and forth relative to the front end surface, the space size of the air outlet channel is adjusted to control the air inlet amount of the air outlet channel, and the change trend of the space size and the air inlet amount is the same;

the front panel moves up and down relative to the front end face, the opening degree of the lower air outlet is adjusted to control the air inlet amount of the air outlet channel, and the change trend of the opening degree and the air inlet amount is opposite.

Wherein, preferred scheme is, horizontal air-out mode includes:

the front panel moves to the topmost end;

the air deflector is arranged on the lower end face of the lower air outlet;

wherein, the wind that the lower air outlet blew out is horizontal to be blown out through the aviation baffle drainage.

Wherein, the preferred scheme is: the tail end of the upper end surface of the air deflector is tilted upwards, the lower end surface of the air deflector is a flat surface, and the lower end surface of the air deflector arranged at the lower air outlet shows that the upper end surface of the air deflector faces upwards and is in a forward horizontal state or a forward similar horizontal state.

Preferably, the crosswind mode includes:

the front panel moves to the topmost end;

the air deflector inclines forwards and upwards;

the air blown out from the lower air outlet is blown into the air outlet channel through the air deflector and is blown out through the air outlet channel.

Wherein, the preferred scheme is: the lower end face of the air deflector is a flat face and is arranged upwards, the top of the air outlet channel is provided with an air resistance structure, and air blown out from the lower air outlet is blown into the air outlet channel through the air deflector, blown upwards and blown out to two sides through the air outlet channel.

Wherein, preferred scheme is, quick refrigeration mode includes:

the front panel moves to the topmost end;

the air deflector is in a reverse horizontal state or a reverse horizontal state, and can be shaken to accelerate air disturbance;

the lower end face of the air deflector is a flat face, the tail end of the upper end face of the air deflector is tilted upwards, the lower end face of the air deflector faces upwards, and the air deflector is positioned in the middle of the lower air outlet; the air blown out from the lower air outlet is divided into an upper part and a lower part by the air deflector, the air at the upper part is drained and blown out horizontally through the lower end surface of the air deflector, and the air at the lower part is blown out forwards and/or forwards and downwards through the middle frame.

Preferably, the angle air supply mode includes:

the front panel moves to the topmost end;

the air deflector inclines forwards and downwards;

the lower end face of the air deflector is a flat face, the tail end of the upper end face of the air deflector is tilted upwards, the lower end face of the air deflector faces upwards, and the end part of the air deflector is positioned in the middle of the lower air outlet; the air blown out from the lower air outlet is guided by the air guide plate and blown out towards the angle of the air guide plate.

Preferably, the heating vertical mode includes:

the front panel moves to the topmost end;

the air deflector is vertically arranged;

the air guide plate guides the hot air blown out from the lower air outlet to vertically move downwards.

Preferably, the breeze mode includes:

the front panel moves back and forth;

the air deflector inclines forwards and downwards;

the air blown out from the lower air outlet is partially guided by the air guide plate and blown out towards the angle of the air guide plate, and partially blown into the air outlet channel, so that the total air volume of the blown air is reduced.

Compared with the prior art, the front panel air conditioner has the advantages that the functional modes are set and are realized by controlling the rotating position of the air deflector and/or the moving position of the front panel in a matched mode, so that the requirements of various functional modes based on the front panel air conditioner are met, different working environments or user requirements are met, user experience is improved, and the multi-mode control mode of the front panel air conditioner is optimized.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic side sectional view of an air conditioner based on a shutdown mode according to the present invention;

FIG. 2 is a schematic side sectional view of the soft wind mode-based air conditioner of the present invention;

FIG. 3 is a schematic side view of a cross-sectional structure of an air conditioner according to the present invention, based on a horizontal outlet mode;

FIG. 4 is a schematic side sectional view of the cross-wind mode air conditioner of the present invention;

FIG. 5 is a schematic side sectional view illustrating an air conditioner according to the present invention based on a rapid cooling mode;

FIG. 6 is a schematic side sectional view of an air conditioner based on an angular blowing mode according to the present invention;

fig. 7 is a schematic side sectional view illustrating an air conditioner based on a heating vertical mode according to the present invention;

fig. 8 is a schematic side sectional view of the air conditioner based on the breeze mode according to the present invention.

Detailed Description

The preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 8, the present invention provides an air conditioner having a front panel and a multi-mode control method thereof.

The air conditioner includes a middle frame 100, a lower outlet 110 provided on the middle frame 100, and a wind guide plate 300 provided at the lower outlet 110 of the middle frame 100, a front panel 200 movably provided on a front end surface of the middle frame 100, the front panel 200 forming a wind outlet passage 101 while moving back and forth with respect to the front end surface. Specifically, the front panel 200 can move, preferably move back and forth and up and down, on the front end surface of the middle frame 100, the air inlet amount of the air outlet channel 101 is controlled by controlling the movement of the front panel 200 and adjusting the spatial position thereof, and the air blown from the lower air outlet 110 to the air outlet channel 101 is blown outwards along the edge of the front panel 200; the air guiding plate 300 can move on the middle frame 100 by a large angle to change the direction of the air blown by the lower air outlet 110, so as to meet the requirements of the wind direction in different functional modes.

The multi-mode control method is provided with at least one functional mode, and the functional mode is one of a shutdown mode, a soft wind mode, a horizontal air outlet mode, a side wind mode, a quick refrigeration mode, an angle air supply mode, a heating vertical mode and a small wind mode; and, the functional mode is realized by controlling the rotation position of the air deflector 300 and/or the movement position of the front panel 200 in a matching manner, thereby satisfying the requirements of various functional modes based on the front panel air conditioner, coping with different working environments or user requirements, improving user experience, and optimizing the multi-mode control mode of the front panel air conditioner.

As shown in FIG. 1, the present invention provides a preferred embodiment of the shutdown mode.

The air conditioner further comprises a movable switch door, and the shutdown mode comprises:

a1, returning the front panel 200 to the middle frame 100;

a2 and the air deflector 300 are arranged on the lower end surface of the lower air outlet 110;

a3, the movable switch door extends out of the front end of the lower air outlet 110 and is abutted against or close to the air deflector 300.

Specifically, the shutdown mode indicates that the air conditioner is in a shutdown state, and the front panel 200, the air deflector 300, and the movable switch door are all restored to the initial positions, so that the air conditioner forms a non-opened whole, and the relative sealing of the internal structure is realized. Preferably, the a1 and the A3 should be linked or moved in a linking manner, that is, the movable switch door extends out of the front end of the lower air outlet 110 and abuts against or approaches the air deflector 300 when the front panel 200 is returned to the middle frame 100 by a specific linking structure or a sensing manner, and similarly, the air deflector 300 in the a2 is also preferably returned to facilitate the abutting against or approaching of the movable switch door, wherein the return of the air deflector 300 is in a forward horizontal arrangement.

As shown in FIG. 2, the present invention provides a preferred embodiment of the soft mode.

The soft wind mode includes:

b1, the front panel 200 can move back and forth or move up and down relative to the middle frame 100;

b2 and the air deflector 300 are arranged on the lower end surface of the lower air outlet 110.

The air blown out from the lower air outlet 110 partially enters the air outlet channel 101, and the front panel 200 is controlled to move and adjust the spatial position thereof, so as to control the air inlet amount of the air outlet channel 101.

Specifically, the soft wind mode indicates that the wind blown from the lower outlet 110 enters the outlet channel 101 and is blown from the edge outlet of the outlet channel 101, so that the outlet wind of the air conditioner is relaxed, the soft wind is realized, and the amount of wind blown into the front panel 200 is adjusted by adjusting the moving position of the front panel 200.

In this embodiment, the step of controlling the movement of the front panel 200 and adjusting the spatial position thereof to control the intake air amount of the air outlet channel 101 includes:

b11, the front panel 200 moves back and forth relative to the front end surface, the space size of the air outlet channel 101 is adjusted to control the air inlet amount of the air outlet channel 101, and the change trend of the space size and the air inlet amount is the same direction;

b12, the front panel 200 moves up and down relative to the front end face, and the opening degree of the lower air outlet 110 is adjusted to control the air inlet amount of the air outlet channel 101, wherein the trend of the opening degree and the air inlet amount is opposite.

Depending on the movement pattern or current position of the front panel 200, various soft wind modes can be implemented. The first and the front panels 200 move back and forth relative to the front end surface, and the air quantity blown into the air outlet channel 101 by the lower air outlet 110 is determined by the space size of the air outlet channel 101, so that the strength of the air blown out by the soft air in each direction is adjusted; secondly, the front panel 200 moves up and down relative to the front end face, and the air volume blown into the air outlet channel 101 is adjusted by adjusting the opening degree of the lower air outlet 110, so that the forward air volume of the straight blow is improved, the blowing intensity in each direction is reduced along with the rising of the height, and the horizontal blowing intensity is increased.

Further, the tail end of the upper end surface of the air deflector 300 is tilted upwards, so that part of the air can be guided upwards to blow out obliquely, and more air can be blown into the air outlet channel 101.

In this embodiment, the front panel 200 may perform a reciprocating motion with a certain distance value in the soft wind mode, where the reciprocating motion may be intermittent or continuous, and is used to change the air volume of the lower air outlet 110, so as to optimize the condensation condition of the front end surface of the air deflector 300 or the lower edge of the front panel 200.

As shown in fig. 3, the present invention provides a preferred embodiment of a horizontal air-out mode.

The horizontal air outlet mode comprises:

c1, the front panel 200 moves to the topmost end;

c2, the air deflector 300 is arranged on the lower end surface of the lower air outlet 110;

wherein, the air blown out from the lower air outlet 110 is guided by the air deflector 300 and blown out horizontally.

Specifically, the end of the upper end surface of the air deflector 300 is tilted upward, the lower end surface of the air deflector 300 is a flat surface, and the lower end surface of the air deflector 300 disposed at the lower air outlet 110 indicates that the upper end surface of the air deflector 300 faces upward and is in a forward horizontal state or a forward horizontal state. Due to the matching of the air deflector 300 and the middle frame 100, the spliced position of the air deflector 300 and the middle frame 100 is relatively sealed, so that the air blown out from the lower air outlet 110 is blown out forwards along the upper end surface of the air deflector 300 as far as possible, and the blown air is blown out forwards horizontally due to the fact that the air deflector 300 is in a forward horizontal state or a forward horizontal state.

Certainly, according to the shape of the upper end face of the air deflector 300, the air blown out forward horizontally is only far away from the upper level, and part of the air can be blown out obliquely upward or obliquely downward, but the air in the two directions can be ignored, and the influence on the whole air volume is not great.

As shown in FIG. 4, the present invention provides a preferred embodiment of the crosswind mode.

The crosswind mode includes:

e1, the front panel 200 moves to the topmost end;

e2, the air deflector 300 inclines forwards and upwards;

the air blown out from the lower outlet 110 is blown into the outlet channel 101 through the air deflector 300, and is blown out through the outlet channel 101. Of course, the front panel 200 may not be moved to the topmost end, and the wind blown out from the lower outlet 110 may be blown into the wind outlet channel 101 along the wind deflector 300 as long as the inclination of the wind deflector 300 is ensured to correspond.

Specifically, the lower end surface of the air deflector 300 is a flat surface and is arranged upward, the top of the air outlet channel 101 is provided with the wind resistance structure 210, and the wind blown out from the lower air outlet 110 is blown into the air outlet channel 101 through the air deflector 300, blown upward and blown out to both sides through the air outlet channel 101. Particularly, the air inlet 120 is disposed on the upper end surface of the air-conditioning center frame 100, and a baffle plate serving as a wind resistance structure 210 is horizontally disposed on the upper portion of the air outlet channel 101 near the air inlet 120 to block the upward flow of the wind in the air outlet channel 101 and prevent the reverse suction of the air inlet 120, so that the side wind mode is also a two-side wind blowing mode, the lower side is blocked by the wind deflector 300, the upper side is blocked by the wind resistance structure 210, and the wind blown out from the lower air outlet 110 can only be blown out through the left and right sides of the air outlet channel 101.

As shown in FIG. 5, the present invention provides a preferred embodiment of a rapid chill mold.

The rapid cooling mode includes:

f1, moving the front panel 200 to the topmost end;

f2, the air deflector 300 is in a reverse horizontal state or a reverse similar horizontal state, and the air deflector 300 can be shaken to accelerate air disturbance;

the lower end surface of the air deflector 300 is a flat surface, the end of the upper end surface of the air deflector 300 is tilted upwards, the lower end surface of the air deflector 300 faces upwards, and the air deflector 300 is positioned in the middle of the lower air outlet 110; the wind blown out from the lower outlet 110 is divided into an upper part and a lower part by the wind deflector 300, the wind at the upper part is guided by the lower end surface of the wind deflector 300 and blown out horizontally, and the wind at the lower part is blown out forwards and/or forwards and downwards through the middle frame 100.

Specifically, since the rotating shaft 301 of the wind deflector 300 is above the upper end surface, the positions of each angle of the wind deflector 300 are different when the wind deflector 300 rotates around the rotating shaft 301, for example, the wind deflector 300 is disposed at 0 degree (i.e., the wind deflector 300 is disposed in a forward horizontal state) on the lower end surface of the lower outlet 110 and is hermetically spliced with the middle frame 100, and after the wind deflector 300 rotates 180 degrees, the current position of the wind deflector 300 is parallel to the position at 0 degree, but is above the position at 0 degree, i.e., at the middle position of the lower outlet 110, wherein the middle position is not the middle position but is not the end edge position.

Particularly, in the drainage process of the air deflector 300, the air deflector 300 is shaken, the direction disorder of wind is improved, the air disturbance is accelerated, and the quick refrigeration effect is realized.

As shown in FIG. 6, the present invention provides a preferred embodiment of the angular blowing mode.

The angle air supply mode comprises the following steps:

g1, the front panel 200 moves to the topmost end;

g2, the air deflector 300 inclines forwards and downwards;

the lower end surface of the air deflector 300 is a flat surface, the end of the upper end surface of the air deflector 300 is tilted upwards, the lower end surface of the air deflector 300 faces upwards, and the end part of the air deflector 300 is positioned in the middle of the lower air outlet 110; the air blown out from the lower outlet 110 is guided by the air guide plate 300 and blown out at an angle toward the air guide plate 300. Specifically, in the air outlet process of the lower air outlet 110, the air deflector 300 swings around the rotating shaft 301, so that the blowing angle of the air is changed, and the air supply operation at different angles or specific angles is met.

As shown in FIG. 7, the present invention provides a preferred embodiment of the heating vertical mode.

The heating vertical mode includes:

h1, front panel 200 moves to the topmost end;

h2 and the air deflector 300 are vertically arranged;

the air guide plate 300 guides the hot wind blown out from the lower outlet 110 to move vertically downward.

In the hot air mode, since the hot air is easy to rise, the air needs to be guided by the air deflector 300 to move vertically downward when the air is blown out from the lower air outlet 110, so as to facilitate the lower layer of hot air flow.

As shown in FIG. 8, the present invention provides a preferred embodiment of the breeze mode.

The breeze mode includes:

j1, front panel 200 moving back and forth;

j2, wind deflector 300 inclines forwards and downwards;

the air blown out from the lower outlet 110 is partially guided by the air deflector 300, blown out toward the angle of the air deflector 300, and partially blown into the air outlet channel 101, so as to reduce the total air volume of the blown air.

The soft wind mode is characterized in that the soft wind mode belongs to a half-soft wind half-angle air supply state, partial wind is blown into the air outlet channel 101, soft wind is achieved, the total amount of wind blown out in a direct horizontal or oblique downward blowing mode is reduced, and the blowing angle of the wind which is not blown into the air outlet channel 101 and remains in a small wind mode is determined according to the swing angle of the air deflector 300.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the present invention, but rather as embodying the invention in a wide variety of equivalent variations and modifications within the scope of the appended claims.

Claims (12)

1. A multi-mode control method of an air conditioner with a front panel, the air conditioner comprises a middle frame, a lower air outlet arranged on the middle frame and an air deflector arranged at the lower air outlet of the middle frame, the front panel is movably arranged on the front end surface of the middle frame, and the front panel forms an air outlet channel when moving back and forth relative to the front end surface, and the multi-mode control method is characterized in that: the multi-mode control method is provided with at least one functional mode, wherein the functional mode is one of a shutdown mode, a soft wind mode, a horizontal air outlet mode, a side wind mode, a quick refrigeration mode, an angle air supply mode, a heating vertical mode and a small wind mode; and the functional mode is realized by controlling the rotation position of the air deflector and/or the movement position of the front panel in a matching way.

2. The multi-mode control method of claim 1, wherein the air conditioner further comprises a movable switch door, and the shutdown mode comprises:

the front panel is returned to the middle frame;

the air deflector is arranged on the lower end face of the lower air outlet;

the movable switch door extends out of the front end of the lower air outlet and is abutted against or close to the air deflector.

3. The multi-mode control method of claim 1, wherein the soft wind mode comprises:

the front panel can move back and forth or move up and down relative to the middle frame;

the air deflector is arranged on the lower end face of the lower air outlet;

wherein, the wind part that lower air outlet blew out is gone into in the air-out passageway, and control front panel motion and adjust its spatial position to the intake of control air-out passageway.

4. The multi-mode control method as claimed in claim 3, wherein the step of controlling the movement of the front panel and adjusting the spatial position thereof to control the intake air rate of the outlet air duct comprises:

the front panel moves back and forth relative to the front end surface, the space size of the air outlet channel is adjusted to control the air inlet amount of the air outlet channel, and the change trend of the space size and the air inlet amount is the same;

the front panel moves up and down relative to the front end face, the opening degree of the lower air outlet is adjusted to control the air inlet amount of the air outlet channel, and the change trend of the opening degree and the air inlet amount is opposite.

5. The multi-mode control method according to claim 1, wherein the horizontal wind outlet mode includes:

the front panel moves to the topmost end;

the air deflector is arranged on the lower end face of the lower air outlet;

wherein, the wind that the lower air outlet blew out is horizontal to be blown out through the aviation baffle drainage.

6. The multi-mode control method according to any one of claims 2 to 5, characterized in that: the tail end of the upper end surface of the air deflector is tilted upwards, the lower end surface of the air deflector is a flat surface, and the lower end surface of the air deflector arranged at the lower air outlet shows that the upper end surface of the air deflector faces upwards and is in a forward horizontal state or a forward similar horizontal state.

7. The multi-mode control method of claim 1, wherein the crosswind mode comprises:

the front panel moves to the topmost end;

the air deflector inclines forwards and upwards;

the air blown out from the lower air outlet is blown into the air outlet channel through the air deflector and is blown out through the air outlet channel.

8. The multi-mode control method according to claim 7, characterized in that: the lower end face of the air deflector is a flat face and is arranged upwards, the top of the air outlet channel is provided with an air resistance structure, and air blown out from the lower air outlet is blown into the air outlet channel through the air deflector, blown upwards and blown out to two sides through the air outlet channel.

9. The multi-mode control method of claim 1, wherein the fast cooling mode comprises:

the front panel moves to the topmost end;

the air deflector is in a reverse horizontal state or a reverse horizontal state, and can be shaken to accelerate air disturbance;

the lower end face of the air deflector is a flat face, the tail end of the upper end face of the air deflector is tilted upwards, the lower end face of the air deflector faces upwards, and the air deflector is positioned in the middle of the lower air outlet; the air blown out from the lower air outlet is divided into an upper part and a lower part by the air deflector, the air at the upper part is drained and blown out horizontally through the lower end surface of the air deflector, and the air at the lower part is blown out forwards and/or forwards and downwards through the middle frame.

10. The multi-mode control method according to claim 1, wherein the angular blowing mode includes:

the front panel moves to the topmost end;

the air deflector inclines forwards and downwards;

the lower end face of the air deflector is a flat face, the tail end of the upper end face of the air deflector is tilted upwards, the lower end face of the air deflector faces upwards, and the end part of the air deflector is positioned in the middle of the lower air outlet; the air blown out from the lower air outlet is guided by the air guide plate and blown out towards the angle of the air guide plate.

11. The multi-mode control method of claim 1, wherein the heating vertical mode comprises:

the front panel moves to the topmost end;

the air deflector is vertically arranged;

the air guide plate guides the hot air blown out from the lower air outlet to vertically move downwards.

12. The multi-mode control method of claim 1, wherein the low wind mode comprises:

the front panel moves back and forth;

the air deflector inclines forwards and downwards;

the air blown out from the lower air outlet is partially guided by the air guide plate and blown out towards the angle of the air guide plate, and partially blown into the air outlet channel, so that the total air volume of the blown air is reduced.

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